Hydraulic conductivity prediction for sandy soils

Ground Water

Volumn 42, Issue 3, 2004, Pages 459-464

  Cronican, Amy E ^a   Gribb, Molly M ^b  

^a SandME Inc   (United States)

^b Boise State University   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CRUDE PETROLEUM; ENVIRONMENTAL IMPACT; HYDRAULIC CONDUCTIVITY; MATHEMATICAL MODELS; REGRESSION ANALYSIS; SOILS;

SANDY SOILS; SOIL LEACHABILITY MODELS;

GROUNDWATER;

PETROLEUM; SILICON DIOXIDE;

HYDRAULIC CONDUCTIVITY; NUMERICAL MODEL; SANDY SOIL; SOIL POLLUTION; SOIL WATER; UNSATURATED FLOW;

ARTICLE; FORECASTING; SOIL; SOIL POLLUTANT; SOLUBILITY; THEORETICAL MODEL; VALIDATION STUDY; WATER FLOW; WATER POLLUTANT;

FORECASTING; MODELS, THEORETICAL; PETROLEUM; SILICON DIOXIDE; SOIL; SOIL POLLUTANTS; SOLUBILITY; WATER MOVEMENTS; WATER POLLUTANTS;

NORTH AMERICA; SOUTH CAROLINA; UNITED STATES;

EID: 2342526636     PISSN: 0017467X     EISSN: None     Source Type: Journal    
DOI: 10.1111/j.1745-6584.2004.tb02694.x     Document Type: Article

References (30)

1. Ahuja, L.R., D.K. Cassel, R.R. Bruce, and B.B. Barnes. 1989. Evaluation of spatial distribution of hydraulic conductivity using effective porosity data. Soil Science 148, no. 6: 404-411.
2. Alyamani, M.S., and Z. Sen. 1993. Determination of hydraulic conductivity from complete grain-size distribution curves. Ground Water 31, no. 4: 551-555.
3. Bene, K.J. 1996. Measurement methods and data analyses for vadose zone characterization at a vegetated field site. Ph.D. dissertation, Department of Civil and Environmental Engineering, University of South Carolina, Columbia.
4. Bene, K.J. 1997. Unpublished field data, Department of Civil and Environmental Engineering, University of South Carolina, Columbia.
5. Dane, J.H., D.K. Cassel, J.M. Davidson, W.L Pollans, and V.L. Quisenberry. 1983. Physical characteristics of soil in the Southern Region Troup and Lakeland series. Southern Cooperative Service Bulletin 262. Auburn, Alabama: Alabama Agricultural Experiment Station.
6. Dane, J.H., and W.E. Puckett. 1992. Field soil hydraulic properties based on physical and mineralogical information. In Proceedings of an International Workshop: Indirect Methods for Estimating the Hydraulic Properties of Unsaturated Soils, ed. M.Th. van Genuchten and F.J. Leij, 389-403. Riverside, California: University of California at Riverside Printing Office.
7. Eddy-Dilek, C.A., B.B. Looney, T.C. Hazen, R.L. Nichols, C.B. Fliermans, W.H. Parker, J.M. Dougherty, D.S. Kaback, and J.L. Simmons. 1993. Post-test evaluation of the geology, geochemistry, microbiology, and hydrology of the in situ air stripping demonstration site at the Savannah River Site. Savannah River Technology Center, Environmental Sciences Section, WSRC-TR-93-369, Revision 0.
8. Environmental Protection Agency. 2001a. RBCA implementation case studies, no. 3: A historical perspective on the South Carolina UST corrective action program, http://www.epa.gov/ swerustl/rbdm/sccase.htm.
9. Environmental Protection Agency. 2001b. Current drinking water standards. Office of Drinking Water. http://www.epa.gov/ safewater/mcl.html.
10. Environmental Protection Division. 1998. Georgia Department of Natural Resources' Guidance document Underground storage tank release: Corrective action plan (CAP) part A. http://www.georgianet.org/dnr/environ/techguide_files/lpb/u stcap-a698.pdf).
11. Franzmeier, D.P. 1991. Estimation of hydraulic conductivity from effective porosity data for some Indiana soils. Soil Science Society of America Journal 55, 1801-1803.
12. Green, W.H., and G.A. Ampt. 1911. Studies on soil physics: I. Flow of air and water through soils. Journal of Agricultural Science 4, 1-24.
13. Hazen, A. 1892. Some physical properties of sands and gravels. Massachusetts State Board of Health Annual Report, 539-556.
14. Jabro, J.D. 1992. Estimation of saturated hydraulic conductivity of soils from particle size distribution and bulk density data. Journal of the American Society of Agricultural Engineers 35, no. 2: 557-560.
15. Kozeny, J. 1953. Das wasser in boden, grundwasserbewegung. Hydraulik 280-445. Vienna, Austria: Springer-Verlag.
16. Kodesova, R., S.E. Ordway, M.M. Gribb, and J. Simunek, 1999. Estimation of soil hydraulic properties with the cone permeameter: Field studies. Soil Science 164, no. 8: 527-541.
17. Krumbein, W.C., and G.D. Monk. 1943. Permeability as a function of the size parameters of unconsolidated sands. In Transactions of the American Institute of Mining, Metallurgical and Petroleum Engineers 151, 153-163.
18. Lebron, I., M.G. Schaap, and D.L. Suarez. 1999. Saturated hydraulic conductivity prediction from microscopic pore geometry measurements and neural network analysis. Water Resources Research 35, no. 10: 3149-3158.
19. Marshall, T.J. 1958. A relation between permeability and size distribution of pores. Journal of Soil Science 9, 1-8.
20. Masch, F.D., and K.J. Denny. 1966. Grain-size distribution and its effect on the permeability of unconsolidated sands. Water Resources Research 2, no. 4: 665-677.
21. Pachepsky, Y.A., W.J. Rawls, and D.J. Timlin. 1999. The current status of pedotransfer functions: Their accuracy, reliability, and utility in field- and regional-scale modeling. In Assessment of Non-Point Source Pollution in the Vadose Zone: Geophysical Monograph 108, ed. D.L. Corwin, K. Loague, and T.R. Ellsworth, 223-234. Washington, D.C.: American Geophysical Union.
22. Puckett, W.E., J.H. Dane, and B.F. Hajek. 1985. Physical and mineralogical data to determine soil hydraulic properties. Soil Science Society of America Journal 49, no. 4: 831-836.
23. Rawls, W.J., and D.L. Brakensiek. 1989. Estimation of soil water retention and hydraulic properties. In Unsaturated Flow in Hydrologic Modeling Theory and Practice, ed. H.J. Morel-Seytoux, 275-300. Dordrecht, The Netherlands: Kluwer Academic Publishers.
24. SAS Institute. 1996. The SAS System for Windows v. 6.12, User's Manual. Cary, North Carolina.
25. Schaap, M.G. 1999. Rosetta v 1.0. Riverside, California: U.S. Salinity Laboratory ARS-USDA, http://www.ussl.ars.usda .gov/models/rosetta/rosetta.htm.
26. Schaap, M.G., F.J. Leij, and M.Th. van Genuchten. 1998. Neural network analysis for hierarchical prediction of soil hydraulic properties. Soil Science Society of America Journal 62, 847-855.
27. Shepherd, R.G. 1989. Correlations of permeability and grain size. Ground Water 27, no. 5: 633-638.
28. South Carolina Department of Health and Environmental Control. 1998. South Carolina risk-based corrective action for petroleum releases guidance document. Columbia, South Carolina: Bureau of Underground Storage Tank Management.
29. Sperry, J.M., and J.J. Peirce. 1995. A model for estimating the hydraulic conductivity of granular material based on grain shape, grain size, and porosity. Ground Water 33, no. 6: 892-898.
30. Uma, K.O., B.C.E. Egboka, and K.M. Onuoha. 1989. New statistical grain-size method for evaluating the hydraulic conductivity of sandy aquifers. Journal of Hydrology 108, 343-366.